// Boost.Geometry (aka GGL, Generic Geometry Library) // Copyright (c) 2012-2014 Barend Gehrels, Amsterdam, the Netherlands. // Use, modification and distribution is subject to the Boost Software License, // Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) #ifndef BOOST_GEOMETRY_STRATEGIES_CARTESIAN_BUFFER_END_ROUND_HPP #define BOOST_GEOMETRY_STRATEGIES_CARTESIAN_BUFFER_END_ROUND_HPP #include #include #include #include #include #include namespace boost { namespace geometry { namespace strategy { namespace buffer { /*! \brief Let the buffer create rounded ends \ingroup strategies \details This strategy can be used as EndStrategy for the buffer algorithm. It creates a rounded end for each linestring-end. It can be applied for (multi)linestrings. Also it is applicable for spikes in (multi)polygons. This strategy is only applicable for Cartesian coordinate systems. \qbk{ [heading Example] [buffer_end_round] [heading Output] [$img/strategies/buffer_end_round.png] [heading See also] \* [link geometry.reference.algorithms.buffer.buffer_7_with_strategies buffer (with strategies)] \* [link geometry.reference.strategies.strategy_buffer_end_flat end_flat] } */ class end_round { private : std::size_t m_points_per_circle; template < typename Point, typename PromotedType, typename DistanceType, typename RangeOut > inline void generate_points(Point const& point, PromotedType alpha, // by value DistanceType const& buffer_distance, RangeOut& range_out) const { PromotedType const two = 2.0; PromotedType const two_pi = two * geometry::math::pi(); std::size_t point_buffer_count = m_points_per_circle; PromotedType const diff = two_pi / PromotedType(point_buffer_count); // For half circle: point_buffer_count /= 2; point_buffer_count++; for (std::size_t i = 0; i < point_buffer_count; i++, alpha -= diff) { typename boost::range_value::type p; set<0>(p, get<0>(point) + buffer_distance * cos(alpha)); set<1>(p, get<1>(point) + buffer_distance * sin(alpha)); range_out.push_back(p); } } template static inline T calculate_angle(P1 const& from_point, P2 const& to_point) { typedef P1 vector_type; vector_type v = from_point; geometry::subtract_point(v, to_point); return atan2(geometry::get<1>(v), geometry::get<0>(v)); } public : //! \brief Constructs the strategy //! \param points_per_circle points which would be used for a full circle explicit inline end_round(std::size_t points_per_circle = 90) : m_points_per_circle(points_per_circle) {} #ifndef DOXYGEN_SHOULD_SKIP_THIS //! Fills output_range with a flat end template inline void apply(Point const& penultimate_point, Point const& perp_left_point, Point const& ultimate_point, Point const& , buffer_side_selector side, DistanceStrategy const& distance, RangeOut& range_out) const { typedef typename coordinate_type::type coordinate_type; typedef typename geometry::select_most_precise < coordinate_type, double >::type promoted_type; promoted_type const alpha = calculate_angle(perp_left_point, ultimate_point); promoted_type const dist_left = distance.apply(penultimate_point, ultimate_point, buffer_side_left); promoted_type const dist_right = distance.apply(penultimate_point, ultimate_point, buffer_side_right); if (geometry::math::equals(dist_left, dist_right)) { generate_points(ultimate_point, alpha, dist_left, range_out); } else { promoted_type const two = 2.0; promoted_type dist_half_diff = (dist_left - dist_right) / two; if (side == buffer_side_right) { dist_half_diff = -dist_half_diff; } Point shifted_point; set<0>(shifted_point, get<0>(ultimate_point) + dist_half_diff * cos(alpha)); set<1>(shifted_point, get<1>(ultimate_point) + dist_half_diff * sin(alpha)); generate_points(shifted_point, alpha, (dist_left + dist_right) / two, range_out); } } template static inline NumericType max_distance(NumericType const& distance) { return distance; } //! Returns the piece_type (flat end) static inline piece_type get_piece_type() { return buffered_round_end; } #endif // DOXYGEN_SHOULD_SKIP_THIS }; }} // namespace strategy::buffer }} // namespace boost::geometry #endif // BOOST_GEOMETRY_STRATEGIES_CARTESIAN_BUFFER_END_ROUND_HPP